New processes for homojunction silicon solar cells doping: From beam line to plasma immersion ion implantation

2016 16th International Workshop on Junction Technology (IWJT) Pub Date : 2016-05-09 DOI:10.1109/IWJT.2016.7486671

M. Coig, F. Milési, J. Lerat, T. Desrues, J. Le Perchec, A. Lanterne, L. Lachal, F. Mazen

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引用次数: 3

Abstract

The doping of n-type silicon solar cells was investigated using two ion implantation techniques: beam line and plasma immersion. Initially, we evaluated the benefits of beamline ion implantation in replacement of diffusion anneal doping process. Two different annealing routines were studied. The first one using a single annealing to activate both B implanted emitter and P implanted BSF, while the second one used two different annealing to separately activate each dopant. Good yield was reached with a record cell of 20.33% efficiency. Secondly, we investigated the doping by plasma immersion ion implantation where the final objective was the fabrication of a solar cell fully doped by plasma. BF3 and B2H6 were compared as precursor gases for the boron emitter doping, while PH3 was used for the BSF doping. Hybrid cells were fabricated using both implantation techniques and a maximum efficiency of 19.8% was obtained. First cells fully doped by plasma shown promising results with a yield of 18.8%.

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同结硅太阳电池掺杂新工艺:从束流线到等离子体浸没离子注入

采用离子束线和等离子体浸泡两种离子注入技术研究了n型硅太阳电池的掺杂。首先，我们评估了束线离子注入取代扩散退火掺杂工艺的好处。研究了两种不同的退火程序。第一个使用单一退火来激活B注入的发射极和P注入的BSF，而第二个使用两种不同的退火来分别激活每种掺杂剂。收率达到创纪录的20.33%。其次，我们研究了等离子体浸没离子注入的掺杂，最终目标是制备完全等离子体掺杂的太阳能电池。比较了BF3和B2H6作为硼发射极掺杂的前驱体气体，而PH3用于BSF掺杂。采用两种方法制备了杂交细胞，最高效率为19.8%。第一个完全由等离子体掺杂的细胞显示出有希望的结果，产率为18.8%。

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2016 16th International Workshop on Junction Technology (IWJT)

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